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| In the subsequent chapters, we will delve deeper into these topics with a framing informed by autonomy abstractions as shown in the figure below. | In the subsequent chapters, we will delve deeper into these topics with a framing informed by autonomy abstractions as shown in the figure below. | ||
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| These topics will be addressed at the conceptual level and also examined in specific fashion for the four physical domains (example figure below). | These topics will be addressed at the conceptual level and also examined in specific fashion for the four physical domains (example figure below). | ||
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| - | **Productization Lessons and Assessments: | + | |
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| - | Key lessons for productization include: | + | |
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| - | - Engineers must understand their products operate inside a governance structure consisting of laws, regulations, | + | |
| - | - In the case of autonomy, there are many historical standards, but standard development is also under development. | + | |
| - | - A very key aspect of product design is the expectation function for the product. This expectation function is key to communication from a marketing perspective and also from a legal liability perspective. | + | |
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| - | ^ Domain ^ Primary Standards Body ^ Key Autonomy Standard ^ | + | |
| - | | Ground | SAE | SAE J3016 | | + | |
| - | | Ground | ISO | ISO 26262, ISO 21448 | | + | |
| - | | Ground | UNECE | UN R157 | | + | |
| - | | Airborne | RTCA | DO-178C, DO-365 | | + | |
| - | | Airborne | FAA/EASA | UAV autonomy certification | | + | |
| - | | Marine | IMO | MASS autonomy levels | | + | |
| - | | Marine | DNV | Autonomous ship standards | | + | |
| - | | Space | NASA | ALFUS autonomy framework | | + | |
| - | | Space | CCSDS | Spacecraft autonomy protocols | | + | |
| - | | Cross-domain | IEEE | IEEE 7000 series | | + | |
| - | | Cross-domain | IEC | IEC 61508 | | + | |
| - | | Cross-domain | NIST | AI Risk Management Framework | | + | |
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| - | Exercises and References | + | |
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| - | ^ Section ^ Project Title ^ Objective ^ Technical Scope ^ Deliverables ^ Learning Outcomes ^ | + | |
| - | | 2.0 Autonomous Systems Fundamentals | Cross-Domain Autonomy Architecture Design | Understand how autonomy architectures differ across ground, airborne, marine, and space domains. | Define sensing, compute, control, and communication architecture for one system in each domain; analyze environmental constraints and failure modes. | Architecture diagrams (5–10 page report). | Understand how environment drives autonomy architecture, | + | |
| - | | 2.1 Definitions, | + | |
| - | | 2.2 Legal, Ethical, and Regulatory Frameworks | Autonomous System Liability Case Study | Understand relationship between validation, expectation functions, and legal liability. | Analyze a historical accident scenario; determine liability; evaluate compliance with ISO, SAE, FAA, or NASA frameworks. | Legal liability analysis report; governance compliance evaluation. | Understand how governance frameworks assign responsibility and require validation evidence. | | + | |
| - | | 2.3 Introduction to Validation and Verification | Operational Design Domain (ODD) and V&V Development | Learn how to construct a high-level validation plan for an autonomous system. | Define ODD; generate validation scenarios; define correctness criteria; develop validation workflow including simulation and physical tests. | Complete high-level V&V plan document; ODD, coverage, and correctness criteria. | Understand structure of validation plans and role of ODD, coverage, and correctness criteria. | | + | |
| - | | 2.4 Physics-Based vs Decision-Based Validation | Comparative Validation of Deterministic vs AI Systems | Understand validation complexity differences between physics-based and AI-based systems. | Construct a V&V plan for a physics-based function and also for a digital function. | Comparative report on testing methodologies. | Understand fundamental differences between validating physics-based and AI-based systems. | | + | |
| - | | 2.5 Validation Requirements Across Domains | Domain-Specific Validation Design | Learn how validation requirements differ across ground, airborne, marine, and space domains. | Select domain; define hazards, validation methods, certification requirements, | + | |
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| - | Industries | + | |
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| - | ^ Type ^ Description ^ Example Players (Companies / Organizations) ^ | + | |
| - | | Regulators & Government Agencies | Define laws, certification pathways, and operational constraints for autonomous systems across domains (ground, air, marine, space). They translate legislation into enforceable rules and approvals. | NHTSA, FAA, EASA, International Maritime Organization, | + | |
| - | | Standards Organizations / Industry Consortia | Develop technical standards, safety frameworks, and autonomy classification systems that regulators and industry rely on (e.g., SAE levels, ISO safety standards). | SAE International, | + | |
| - | | Legal & Advisory Firms | Interpret liability, compliance, and regulatory frameworks; support litigation, risk assessment, and policy strategy for autonomy deployments. | Baker McKenzie, DLA Piper, Latham & Watkins | | + | |
| - | | Certification & Testing Authorities | Provide independent validation, certification audits, and compliance verification against safety standards (ASIL, DAL, etc.). Critical for market entry. | TÜV SÜD, UL Solutions, DNV | | + | |
| - | | Simulation & Digital Twin Software Providers | Provide tools for scenario-based validation, digital twins, and V&V workflows across autonomy stacks (SIL/HIL, scenario generation, formal testing). | NVIDIA (DRIVE Sim), MathWorks, Ansys, Siemens | | + | |
| - | | Test Track & Physical Testing Infrastructure Providers | Operate controlled environments for real-world validation (proving grounds, UAV corridors, maritime test ranges). Bridge sim-to-real validation. | American Center for Mobility, MCity, FAA UAV Test Sites | | + | |
